KR101570207B1 - Image-sensing module for reducing its whole thickness and method of manufacturing the same - Google Patents

Abstract

There is provided an image sensing module for reducing an overall thickness including an image sensing unit, a light projecting unit, a substrate unit, and a lens unit. The image sensing unit includes an image sensing member having an image sensing area at the top. The light projecting unit includes a translucent member supported above the image sensing member through a plurality of supports. The translucent member corresponds to the image sensing area of the image sensing member. The substrate unit includes a flexible substrate disposed on the image sensing member through a plurality of conductors and electrically connected to the image sensing member. The flexible substrate has at least one through opening for receiving the translucent member, the through opening corresponding to the image sensing area of the image sensing member. The lens unit includes an opaque holder disposed on the flexible substrate and covering the translucent member, and a lens assembly connected to the opaque holder and disposed above the translucent member.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image sensing module and an image sensing module,

The present invention relates to an image sensing module and a method of manufacturing the same, and more particularly, to an image sensing module and a method of manufacturing the same.

As for the conventionally known technologies, the particular advantages of complementary metal-oxide-semiconductor (CMOS) image sensors are their low power consumption and small size. For this reason, CMOS image sensors are convenient to incorporate into portable electronic products of special needs. For example, CMOS image sensors may be convenient to attach to mobile phones and notebook PCs having relatively small engagement spaces. However, the thickness of conventional CMOS image sensors is still not effectively reduced. As a result, how to reduce the thickness of a conventional CMOS image sensor through any structural design improvement is an important task to be solved by the operators in the field.

Embodiments of the present invention provide an image sensing module for reducing the overall thickness and a method of manufacturing the same.

An embodiment of the present invention is to provide an image sensing module for reducing the overall thickness including the image sensing unit, the light projecting unit, the substrate unit and the lens unit. The image sensing unit includes an image sensing member, wherein the image sensing member has an image sensing area at the top of the image sensing member. The translucent unit includes a translucent member supported above the image sensing member via a plurality of supports, wherein the translucent member corresponds to the image sensing area of the image sensing member. Wherein the substrate unit comprises a flexible substrate disposed on the image sensing member through a plurality of conductors and electrically connected to the image sensing member, wherein the flexible substrate includes at least one through opening for receiving the translucent member And at least one of the through openings corresponds to the image sensing area of the image sensing member. The lens unit includes an opaque holder disposed on the flexible substrate and covering the translucent member, and a lens assembly connected to the opaque holder and disposed above the translucent member.

Another embodiment of the present invention is to provide an image sensing module for reducing the overall thickness including the image sensing unit, the light projecting unit, the substrate unit and the lens unit. The image sensing unit includes an image sensing member, wherein the image sensing member has an image sensing area at the top of the image sensing member. The light transmitting unit includes one translucent member supported above the image sensing member through a plurality of supports, wherein the translucent member corresponds to the image sensing area of the image sensing member. The substrate unit includes a flexible substrate electrically connected to the image sensing member. Wherein the lens unit comprises an opaque holder disposed on the flexible substrate and covering the translucent member, and a lens assembly connected to the opaque holder and disposed above the translucent member, wherein the opaque holder has at least two And an upper support angle for supporting the translucent member in a downward direction. More specifically, the image sensing area of the image sensing member provides a first alignment reference surface, and the translucent member is further arranged along the first alignment reference surface provided by the image sensing area, Wherein the second alignment reference surface is provided on the upper surface of the translucent member and the opaque holder is disposed on the upper surface of the translucent member along the second alignment reference surface provided by the translucent member, And directly contacts the upper surface of the translucent member, wherein the translucent member and the opaque holder are sequentially stacked on the image sensing member.

Another embodiment of the present invention provides a method of manufacturing an image sensing module for reducing overall thickness, the method comprising: providing an image sensing member having an image sensing area at a top; Supporting the translucent member above the image sensing member through a plurality of supports to correspond to the image sensing area of the image sensing member; A flexible substrate having at least one through opening corresponding to the image sensing area of the image sensing member and adapted to receive the translucent member and electrically connected to the image sensing member via a plurality of conductors, ; And a lens assembly disposed on the flexible substrate, the lens unit including an opaque holder held on the flexible substrate and covering the translucent member, and a lens assembly connected to the opaque holder and disposed above the translucent member, on the flexible substrate do.

Advantageous effects of the present invention are that the image sensing module and its manufacturing method provided by the embodiment of the present invention are characterized in that the light projecting unit includes a translucent member supported above the image sensing member via a plurality of supports, And the flexible substrate has at least one through-hole for receiving the translucent member ", the image sensing module of the present invention can effectively reduce the thickness of the translucent member. In other words, regardless of whether the thickness of the light transmitting member is large or small, it does not affect the overall thickness of the image sensing module of the present invention.

Further, the image sensing module provided by the embodiment of the present invention is characterized in that "one translucent member supported above the image sensing member through a plurality of supports" and "the opaque holder has at least two direct contacts, Quot ;, the translucent member and the opaque holder can be sequentially stacked on the image sensing member, so that the present invention can be applied to the image sensing member of the opaque holder, It is possible to effectively lower the mounting inclination angle with respect to the mounting surface.

For a better understanding of the features and technical features of the present invention, reference should be made to the following detailed description of the invention and the accompanying drawings. It is to be understood, however, that the appended drawings are provided solely for reference purposes and are not intended to limit the present invention.

1 is a flowchart showing a manufacturing method of an image sensing module for reducing the overall thickness of the first embodiment of the present invention.
Fig. 2 is a view showing the structure in which the translucent member is supported above the image sensing member through the plurality of supports in the first embodiment of the present invention. Fig.
Fig. 3 is a configuration showing the arrangement of the flexible substrate of the first embodiment of the present invention on an image sensing member. Fig.
4 is a view showing an image sensing module for reducing the overall thickness of the first embodiment of the present invention.
5 is a view showing an image sensing module for reducing the overall thickness of the second embodiment of the present invention.

[First Embodiment]

1 to 4, a first embodiment of the present invention provides a method of manufacturing an image sensing module M for reducing the overall thickness, comprising the steps of:

First, as shown in FIGS. 1 and 2, an image sensing member 10 having an image sensing area 100 at its top is provided (S100). For example, the image sensing member 10 may be a complementary metal-oxide-semiconductor (CMOS) image sensor chip or an image sensor having some image sensing function. However, the image sensing member 10 used in the present invention is not limited to the above-described first embodiment.

1 and 2, the translucent member 20 is supported above the image sensing member 10 through a plurality of supports 21 (S102). The translucent member 20 is positioned immediately above the image sensing area 100 of the image sensing member 10 and corresponds exactly to the image sensing area 100 of the image sensing member 10. [ More specifically, the image sensing region 100 of the image sensing member 10 may provide a first alignment reference plane S1, and the translucent member 20 may provide a first alignment reference plane S1, May be disposed above the image sensing area 100 of the image sensing member 10 along the reference plane S1. For example, the support 21 may be an adhesive made of epoxy or silicone, and the translucent member 20 may also be provided on the image sensing member 10 Can be firmly positioned. The translucent member 20 may be a transparent glass positioned directly above the image sensing region 100 and the upper and lower surfaces of the translucent member 20 may be formed of an infrared (IR) Blocking layer 202 may be provided.

More particularly, the plurality of supports 21 may be sequentially connected to one another to form a single encapsulated support surrounding the image sensing area 100. In addition, the translucent member 20 may be disposed on a single encapsulated support to close and open the image sensing area 100. In other words, as shown in FIG. 2, after the translucent member 20 is disposed on the single encapsulated support, it may form a structure similar to a cap cover, By closing the sensing area 100, it is possible to prevent the possibility that the image sensing area 100 is contaminated by the intrusion of fine particles at the time of subsequent processing. However, the translucent member 20 and the support body 21 used in the present invention are not limited to the above-mentioned first embodiment.

1 and 3, the flexible substrate 30 is placed on the image sensing member 10 (S104). The flexible substrate 30 is electrically connected to the image sensing member 10 through the plurality of conductors 31. The flexible substrate 30 includes at least one through hole 300 for receiving the translucent member 20 And the through opening 300 is located just above the image sensing area 100 of the image sensing member 10 and corresponds exactly to the image sensing area 100 of the image sensing member 10. [ For example, the flexible substrate 30 may be any bent circuit board, but the present invention is not limited thereto.

Then, as shown in Figs. 1 and 4, the lens unit 4 is placed on the flexible substrate 30 (S106). For example, the lens unit 4 is connected to one opaque holder 40 and an opaque holder 40 which are disposed on the flexible substrate 30 and cover the translucent member 20, And a lens assembly 41 disposed on the lens barrel. For example, the lens assembly 41 may be composed of a plurality of lenses. In addition, the lens assembly 41 may be fixedly disposed within the opaque holder 40, or may be disposed fluidly within the opaque holder 40.

Referring to FIG. 4 again, the first embodiment of the present invention provides an image sensing module M for reducing the overall thickness of the image sensing unit 1, A unit 2, a substrate unit 3, and a lens unit 4. [ The image sensing unit 1 includes an image sensing member 10, and the top of the image sensing member 10 has an image sensing area 100. The light projecting unit 2 includes a translucent member 20 supported on an upper side of the image sensing member 10 via a plurality of supports 21. The translucent member 20 is disposed on the image sensing area 10 of the image sensing member 10, The upper surface and the lower surface of the translucent member 20 may have an infrared (IR) blocking layer 201 and a reflective (AR) blocking layer 202, respectively. The substrate unit 3 includes a single flexible substrate 30 disposed on the image sensing member 10 through a plurality of conductors 31 and electrically connected to the image sensing member 10, The aperture 30 has at least one through aperture 300 for receiving the translucent member 20 and the through aperture 300 corresponds to the image sensing area 100 of the image sensing member 10. The lens unit 4 includes an opaque holder 40 disposed on the flexible substrate 30 and covering the translucent member 20 and one opposed to the opaque holder 40 and disposed above the translucent member 20, And a lens assembly (41).

Thereby, the translucent member 20 can be disposed directly on the image sensing member 10 through the plurality of supports 21 and can be accommodated in the through-hole 300 of the flexible substrate 30 at the same time, The image sensing module M of the present invention can effectively reduce the thickness of the translucent member 20. [ In other words, regardless of whether the thickness of the translucent member 20 used is large or small, it does not affect the overall thickness of the image sensing module M of the present invention.

More specifically, it may further include an adhesive (not shown) surrounding or adjacent to the conductor 31 around or in the vicinity of each conductor 31, and may also surround each conductor 31 (Not shown) of the flexible substrate 30 can more effectively fix the flexible substrate 30 on the image sensing member 10. In addition, the adhesive body (not shown) surrounding or adjacent to each of the conductors 31 is connected to the corresponding support body 21 so that the external fine particles can pass from the through- It is possible to effectively prevent the image sensing member 10 from being contaminated on the upper surface.

[Second Embodiment]

5, the second embodiment of the present invention provides an image sensing module M for reducing the total thickness, which includes an image sensing unit 1, a light projecting unit 2, a substrate unit 3, Unit (4). The image sensing unit 1 includes an image sensing member 10, and the top of the image sensing member 10 has one image sensing area 100. The translucent unit 2 includes a translucent member 20 supported on the image sensing member 10 via a plurality of supports 21 and the translucent member 20 is disposed on the image sensing area 10 of the image sensing member 10 100). The substrate unit (3) includes a flexible substrate (30) electrically connected to the image sensing member (10). The lens unit 4 includes an opaque holder 40 disposed on the flexible substrate 30 and covering the translucent member 20 and a lens assembly 40 connected to the opaque holder 40 and disposed above the translucent member 20 41). More specifically, the opaque holder 40 has a surrounding supporting leg 400 and at least two top supporting angles 401, and the enclosing supporting angle 400 is passed through the adhesive 402 to the flexible substrate 30, and at least two upper support angles 401 are in direct contact and support the upper surface of the translucent member 20 downward.

More specifically, the image sensing area 100 of the image sensing member 10 may provide a first alignment reference surface S1, and the translucent member 20 may also provide a first alignment reference surface S1, May be disposed above the image sensing area 100 of the image sensing member 10 along the alignment reference plane S1. Further, the upper surface of the translucent member 20 can provide the second alignment reference surface S2. The opaque holder 40 may be disposed on the upper surface of the translucent member 20 and directly contact the upper surface of the translucent member 20 along the second alignment reference surface S2 provided by the translucent member 20. [ As a result, according to the present invention, through the design of the first alignment reference plane S1 provided by the image sensing area 100 and the second alignment reference plane S2 provided by the translucent member 20, the translucent member 20 and the opaque The holder 40 can be sequentially stacked on the image sensing member 10 and therefore the present invention can effectively lower the mounting slope of the opaque holder to the image sensing member.

[Effect of Embodiment]

The advantageous effects of the present invention are that the image sensing module M provided by the embodiment of the present invention and the manufacturing method thereof can be applied to the image sensing member 10 through the plurality of support members 21, Through the design that "the transparent substrate 30 includes the translucent member 20 supported upward" and "the flexible substrate 30 has at least one penetrating opening 300 for accommodating the translucent member 20" So that the image sensing module M can effectively reduce the thickness of the translucent member 20.

The image sensing module M provided by the embodiment of the present invention is configured such that one translucent member 20 and the opaque holder 40 which are supported above the image sensing member 10 through the plurality of support members 21 The translucent member 20 and the opaque holder 40 are provided on the image sensing member 10 with the design of "at least two direct contact and an upper support angle 401 for supporting the translucent member 20 downward. So that the present invention can effectively lower the mounting slope of the opaque holder 40 with respect to the image sensing member 10.

The foregoing is merely a preferred embodiment of the present invention and is not intended to limit the scope of the present invention. Accordingly, it is intended that all of the equivalent technical changes in the specification and drawings be included within the scope of the present invention.

Image sensing module M
Image sensing unit 1
The image sensing member 10
Image sensing area 100
The light projecting unit 2
The light transmitting member 20
Infrared blocking layer 201
The antireflection layer 202
Support 21
The substrate unit 3
The flexible substrate 30
Penetrating opening 300
Conductor 31
Lens unit 4
Opaer Holder 40
Lens assembly 41

Claims (10)

An image sensing unit including an image sensing member having an image sensing area at a top;
A light projecting unit supported above the image sensing member via a plurality of supports and including a translucent member corresponding to the image sensing area of the image sensing member;
A plurality of conductors disposed on the image sensing member and electrically connected to the image sensing member and having at least one through opening corresponding to the image sensing area of the image sensing member and for receiving the translucent member; A substrate unit including a substrate; And,
A lens unit disposed on the flexible substrate and including an opaque holder that covers the translucent member and a lens assembly that is connected to the opaque holder and is disposed above the translucent member;
/ RTI >
Wherein the opaque holder has a surrounding support angle and at least two top support angles,
The envelope support angle is disposed on the flexible substrate through an adhesive,
Wherein the at least two upper support angles are in direct contact with the upper surface of the translucent member and reduce the overall thickness of the upper surface of the translucent member which is directed downward. The method according to claim 1,
Wherein the plurality of supports are sequentially connected to each other to form a single encapsulated support surrounding the image sensing area,
Wherein the translucent member is disposed on the single envelope to close and open the image sensing area,
Wherein the image sensing member is a complementary metal oxide semiconductor image sensor chip,
Wherein the translucent member is a transparent glass positioned directly above the image sensing area,
And an infrared ray blocking layer and an anti-reflection layer are provided on the upper surface and the lower surface of the translucent member, respectively. delete The method according to claim 1,
Wherein the image sensing area of the image sensing member provides a first alignment reference plane,
Wherein the translucent member is disposed above the image sensing area of the image sensing member along the first alignment reference surface provided by the image sensing area,
A second alignment reference surface is provided on the upper surface of the translucent member,
Wherein the opaque holder is disposed on the upper surface of the translucent member and in direct contact with the upper surface of the translucent member along the second alignment reference surface provided by the translucent member,
Wherein the translucent member and the opaque holder are sequentially stacked on the image sensing member. An image sensing unit including an image sensing member having an image sensing area at a top;
A light projecting unit supported above the image sensing member via a plurality of supports and including a translucent member corresponding to the image sensing area of the image sensing member;
A substrate unit including a flexible substrate electrically connected to the image sensing member; And
And a lens unit that is disposed on the flexible substrate and includes an opaque holder that covers the translucent member and a lens assembly that is connected to the opaque holder and that is disposed above the translucent member of the translucent unit,
Wherein the opaque holder has at least two direct contact and an upper support angle that supports the translucent member downward. 6. The method of claim 5,
Wherein the flexible substrate is disposed on the image sensing member through a plurality of conductors,
Wherein the flexible substrate has at least one through opening for receiving the translucent member, the at least one through opening corresponding to the image sensing area of the image sensing member,
Wherein the opaque holder has an encircling support angle disposed on the flexible substrate through an adhesive. 6. The method of claim 5,
Wherein the image sensing area of the image sensing member provides a first alignment reference plane,
Wherein the translucent member is disposed above the image sensing area of the image sensing member along the first alignment reference surface provided by the image sensing area,
A second alignment reference surface is provided on an upper surface of the translucent member,
The opaque holder is disposed on the upper surface of the translucent member and directly contacts the upper surface of the translucent member along the second alignment reference surface provided by the translucent member,
Wherein the translucent member and the opaque holder are sequentially stacked on the image sensing member. Providing an image sensing member having an image sensing area at the top;
Supporting the translucent member above the image sensing member through a plurality of supports to correspond to the image sensing area of the image sensing member;
A flexible substrate electrically connected to the image sensing member via a plurality of conductors and having at least one through opening for receiving the translucent member corresponding to the image sensing area of the image sensing member, ;
Disposing a lens unit on the flexible substrate, the lens unit including an opaque holder disposed on the flexible substrate and covering the translucent member, and a lens assembly connected to the opaque holder and disposed above the translucent member;
/ RTI >
Wherein the opaque holder has a surrounding support angle and at least two top support angles,
The envelope supporting angle is disposed on the flexible substrate through an adhesive
Wherein the at least two upper supporting angles are in direct contact with the upper surface of the translucent member and reduce the overall thickness of the upper surface of the translucent member facing downward. delete 9. The method of claim 8,
Wherein the image sensing area of the image sensing member provides a first alignment reference plane,
Wherein the translucent member is disposed above the image sensing area of the image sensing member along the first alignment reference surface provided by the image sensing area,
A second alignment reference surface is provided on an upper surface of the translucent member,
The opaque holder is disposed on the upper surface of the translucent member and directly contacts the upper surface of the translucent member along the second alignment reference surface provided by the translucent member,
Wherein the translucent member and the opaque holder are sequentially stacked on the image sensing member.

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